CN111774331A - Battery cell grading and grouping method and system based on ACOPOStrak flexible transportation system - Google Patents

Abstract

The invention discloses a battery cell grading and matching method and system based on an ACOPOStrak flexible transportation system. High-speed steering gear, track based on ACOPOStrak flexible transportation system can become arbitrary form and high-speed steering gear, possess product high efficiency reposition of redundant personnel and confluence function, realize electric core stepping to form the battery module according to specific joining in marriage the group mode. The whole device has high flexibility, strong expandability and high efficiency.

Description

Battery cell grading and grouping method and system based on ACOPOStrak flexible transportation system

Technical Field

The invention relates to the technical field of lithium battery transportation, in particular to a battery cell grading and grouping method and system based on an ACOPOStrak flexible transportation system.

Background

In the lithium cell manufacturing process, because factors such as raw and other materials difference, external environment, the same batch monomer electricity core can have the difference in the performance, and the electricity core that has the difference with the performance forms the module through the series-parallel connection, arrives the PACK case again, and the wooden barrel effect that a small amount of poor performance monomer electricity cores produced not only can influence the performance of PACK case, still can influence other monomer electricity core performances in later stage charge-discharge circulation, produces vicious circle effect. Therefore, how to adopt a simple and efficient grading and grouping mode to grade the battery cell according to factors such as voltage, capacity and K value of the battery cell, improve the consistency of the battery cell, and form a PACK box according to a specific grouping mode to maximize the performance of the PACK box is a difficult problem which needs to be solved urgently at present.

Disclosure of Invention

The invention provides a battery cell grading and grouping method and system based on an ACOPOStrak flexible transportation system, which can solve the technical problem.

In order to achieve the purpose, the invention adopts the following technical scheme:

a battery cell grading and grouping method based on an ACOPOStrak flexible transportation system is based on the ACOPOStrak flexible transportation system, wherein,

the ACOPOStrak flexible transportation system is set into a battery cell grading and grouping device which comprises a battery cell loading position, a detection position, each gear grading channel, an off-line + NG quick channel, a grouping position, an empty vehicle return channel, each gear loading and unloading position, a material supplementing quick channel, an NG blanking channel and a conveying trolley;

the method comprises the following steps:

s100, grabbing the mixed-gear battery cell to a conveying trolley of an ACOPOStrak through a feeding robot;

s200, detecting battery cell incoming materials, inserting line in NG and shifting P_iDividing;

s300, according to whether the gear P is required by matching_iBattery cell and gear P_iJudging the flow direction of the battery cell according to the cache number;

s400, feeding the battery cell with insufficient gears;

s500, the battery cells in the i-channel are sequentially transferred to a matching position through a conveying trolley according to matching rules, matching is completed, and the battery cells are grabbed by a stacking robot to be offline.

Further, S200 carries out battery cell incoming material detection, NG rolls off production line and gear P_iDividing;

the method specifically comprises the following steps:

the conveying trolley carrying the battery cell is transferred to a detection position, two code scanning devices are installed at the detection position, a two-dimensional code on a battery cell top cover and a two-dimensional code on the conveying trolley are respectively read, the battery cell with the qualified code reading is automatically bound with the conveying trolley carrying the battery cell by a system, the capacity C, the voltage V, K value and other parameters of the battery cell are called according to the read two-dimensional code on the battery cell top cover, the conveying trolley reading the battery cell two-dimensional code with abnormity is marked as an NG battery cell, and the battery cell is transferred to an NG blanking position through a quick channel by the conveying trolley to realize the off-line;

based on the battery cell capacity C, the voltage V, K value and other parameters, the gear P of the battery cell is determined according to the threshold ranges of the different gear capacity C, the voltage V, K value and other parameters_i。

Further, S300, according to whether the gear P is the gear P required by the group matching or not_iBattery cell and gear P_iJudging the flow direction of the battery cell according to the cache number; the method specifically comprises the following steps:

judging whether the gear to which the battery cell belongs is the gear required by matching the group, and judging the gear P if the gear to which the battery cell belongs is the gear required by matching the group_iWhether the number of the cached battery cells on the grading i channel is smaller than a channel i cache threshold Y or not_iIf the value is less than the cache threshold Y of the i-way of the stepping_iThe battery cell is transferred to a stepping i-channel cache through a transfer trolley; if the value is larger than the stepping i-track cache threshold value Y_iThe battery cell is a redundant gear battery cell, and the battery cell is fed to the upper part through the quick channel by an i-position to realize the offline of the redundant gear battery cell through the conveying trolley; if not belong to and join in marriage the required gear of group, then be unnecessary gear electric core, this electric core passes through quick passage supreme unloading i position through the conveying dolly and realizes unnecessary gear electric core downlead.

Further, S400, feeding the battery cells in insufficient gears;

the method comprises the following steps: judging the number of the cells cached in the i-track stepping mode, and if the number of the cells cached in the i-track stepping mode is smaller than a caching threshold Y of the i-track stepping mode_iAnd detectNo gear P in position_iBattery core supplied material, then gear P_iThe battery cell is a battery cell with insufficient gears, and the battery cell with insufficient gears is loaded and unloaded in an i-position mode; the battery cell with insufficient gears is conveyed to a detection position through a conveying trolley after being on-line, two code scanning devices are installed at the detection position, two-dimensional codes on a top cover of the battery cell and two-dimensional codes on the conveying trolley are respectively read, the battery cell with qualified code reading is automatically bound with the conveying trolley carrying the battery cell by a system, and the battery cell is conveyed to a stepping i-lane cache by the conveying trolley; the conveying trolley for reading the two-dimensional code of the battery cell is marked as the NG battery cell, and the battery cell is conveyed to the NG discharging position through the quick channel through the conveying trolley to realize the NG battery cell offline.

Further, in S200, the threshold ranges of the different gear capacities C, the voltage V, K values K, and other parameters are determined according to the battery cell performance factor capacity class C₁C₂…C_aVoltage class V₁V₂…V_bAnd K value grade K₁K₂…K_cAnd other influencing factors A₁A₂…A_dDividing threshold ranges of all influence factors of different gears, and determining the number n of the gears divided by the battery cell;

n＝(C₁C₂…C_a)*(V₁V₂…V_b)*(K₁K₂…K_c)*(A₁A₂…A_d) (1)。

further, in step S300, i-way cache threshold Y is graded_iJudging that the number of the cells cached in the i-way of the grading is smaller than the caching threshold Y of the i-way of the grading for the system_iAnd no gear P is in the detection position_iThe method comprises the following steps that (1) battery cell feeding is carried out, a system issues a deficient gear feeding instruction to an upper blanking position i as a process starting point, the deficient gear battery cell feeding is realized through the feeding and blanking position i, the system is transferred to a battery cell detection station to complete a detection process, and finally the system is transferred to a stepping i track to be cached as a process end point, wherein the time for completing the process is T(s); each string of cores in a module uses P_iNumber of gear positions M_Pi(ii) a The number M of each series of electric cores in one module; the production line efficiency E is the time required for processing each cell; only/s;

Y_i＝T/(M*E/M_Pi)*1.5 (2)。

on the other hand, the invention also discloses a battery cell grading and grouping system based on the ACOPOStrak flexible transportation system, which comprises the following units:

the feeding unit is used for grabbing the mixed battery cell onto a conveying trolley of the ACOPOStrak through a feeding robot;

cell detection and gear division unit for cell incoming material detection, NG offline and gear P_iDividing;

a cell flow direction judgment unit for judging whether the cell is a gear P required by the group matching_iBattery cell and gear P_iJudging the flow direction of the battery cell according to the cache number;

the insufficient gear battery cell feeding unit is used for feeding the insufficient gear battery cells;

and the gear electric core matching unit is used for sequentially transferring the electric core in the gear i channel to the matching position through the conveying trolley according to the matching rule, completing matching and grabbing the electric core for inserting the wire by the stacking robot.

According to the technical scheme, the battery cell grading and matching method and the battery cell grading and matching system based on the ACOPOStrak flexible transportation system have the advantages that battery cell feeding passes through the detection station, qualified battery cells are detected, the battery cell gear is determined, if the battery cell belongs to the matching gear battery cells, the number of the buffered battery cells in the grading i channel is smaller than the threshold value Y_iThe battery cell is transferred to a stepping i-channel cache by a transfer trolley; if the battery cell does not belong to the group matching gear, the battery cell with the redundant gear is taken off by the quick off-line + NG channel to the upper blanking position i; detecting unqualified cells, and realizing NG cell blanking from a conveying trolley to an NG blanking position through a coil inserting and NG fast channel; the empty conveying trolley waits for feeding from the upper material level through the empty trolley return passage. According to the group rule, the electric core that grades i says transports to the position of joining in marriage in proper order through the conveying trolley according to the rule of joining in marriage, accomplishes and joins in marriage the group, snatchs the electric core by piling up the robot and rolls off the production line, and empty conveying trolley waits the material loading through empty car return channel to the material loading level. When the system detects that the graded i-track cache battery cell is smaller than the threshold value Y_iAnd no gear P is in the detection position_iThe battery core supplies, the system prompts the loading and unloading position to realize the insufficient gear battery core loading, and the conveying trolley supplements the battery core loading through supplementingAnd (4) detecting the materials from the rapid channel to a detection station, transferring the qualified materials to a grading i-channel cache, and waiting for matching.

The high-speed steering gear and the track based on the ACOPOStrak flexible transportation system can be changed into any form and high-speed steering gear, have the functions of high-efficiency shunting and converging of products, realize the grading of the battery cell according to the factors such as voltage, capacity and K value of the battery cell, and form a battery module according to a specific grouping mode.

Drawings

FIG. 1 is a flow chart of a method of the present invention;

fig. 2 is a schematic diagram of a battery cell grading and grouping device according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention.

As shown in fig. 1, the method for cell grading and grouping based on the acopstrak flexible transportation system according to the present embodiment is based on the acopstrak flexible transportation system, wherein,

the battery core grading and grouping device based on the ACOPOStrak flexible transportation system mainly comprises 10 parts of a battery core feeding position, a detection position, each gear grading channel, a down-line + NG quick channel, a grouping position, an empty vehicle return channel, each gear feeding and discharging position, a feeding quick channel, an NG discharging channel and a conveying trolley.

The method comprises the following steps:

s100, grabbing the mixed-gear battery cell to a conveying trolley of an ACOPOStrak through a feeding robot;

s200, detecting battery cell incoming materials, inserting line in NG and shifting P_iDividing;

s300, according to whether the gear P is required by matching_iBattery cell and gear P_iJudging the flow direction of the battery cell according to the cache number;

s400, feeding the battery cell with insufficient gears;

s500, the battery cells in the i-channel are sequentially transferred to a matching position through a conveying trolley according to matching rules, matching is completed, and the battery cells are grabbed by a stacking robot to be offline.

The following is a detailed description:

s100: grabbing the mixed battery cell to a conveying trolley of an ACOPOStrak through a feeding robot;

s200: the method comprises the following steps that a conveying trolley carrying a battery cell is transported to a detection position, two code scanning devices are installed at the detection position and used for reading a two-dimensional code on a battery cell top cover and a two-dimensional code on the conveying trolley respectively, a system automatically binds the battery cell with qualified code reading with the trolley carrying the battery cell, and the battery cell capacity C, the voltage V, K value and other parameters are called according to the read two-dimensional code on the battery cell top cover; the conveying trolley for reading the two-dimensional code of the cell is marked as the NG cell, and the cell transfers the NG blanking position through the quick channel by the conveying trolley to realize the off-line of the NG cell; based on the battery cell capacity C, the voltage V, K value and other parameters, the gear P of the battery cell is determined according to the threshold ranges of the different gear capacity C, the voltage V, K value and other parameters_i；

S300: judging whether the gear to which the battery cell belongs is the gear required by matching the group, and judging the gear P if the gear to which the battery cell belongs is the gear required by matching the group_iWhether the number of the cached battery cells on the grading i channel is smaller than a channel i cache threshold Y or not_iIf the value is less than the cache threshold Y of the i-way of the stepping_iThe battery cell is transferred to a stepping i-channel cache through a transfer trolley; if the value is larger than the stepping i-track cache threshold value Y_iThe battery cell is a redundant gear battery cell, and the battery cell is fed to the upper part through the quick channel by an i-position to realize the offline of the redundant gear battery cell through the conveying trolley; if the battery cell does not belong to the gear required by the matching, the battery cell is a redundant gear battery cell, and the battery cell is fed to the upper blanking position by the quick channel through the conveying trolley to realize the offline of the redundant gear battery cell;

s400: judging the number of the cells cached in the i-track stepping mode, and if the number of the cells cached in the i-track stepping mode is smaller than a caching threshold Y of the i-track stepping mode_iAnd no gear P is in the detection position_iBattery core supplied material, then gear P_iThe battery cell is a battery cell with insufficient gears, and the battery cell with insufficient gears is loaded and unloaded in an i-position mode; not enough shifts are passed through the conveying trolley and are transported to detecting position after electric core reaches standard grade, detect the position installationThe system automatically binds the battery cell with qualified code reading with the conveying trolley carrying the battery cell and is transferred to the grading i-lane cache by the conveying trolley; the conveying trolley for reading the two-dimensional code of the cell is marked as the NG cell, and the cell is conveyed to the NG blanking position through the quick channel by the conveying trolley to realize the NG cell offline;

s500: the battery cores of the i-channel are sequentially transferred to a matching position through a conveying trolley according to matching rules to complete matching, and a stacking robot grabs the battery cores to be off-line;

in S200, the threshold ranges of the different gear capacities C, the voltage V, K values K, and other parameters are according to the battery cell performance factor capacity class C₁C₂…C_aVoltage class V₁V₂…V_bAnd K value grade K₁K₂…K_cAnd other influencing factors A₁A₂…A_dDividing threshold ranges of all influence factors of different gears, and determining the number n of the gears divided by the battery cell;

n＝(C₁C₂…C_a)*(V₁V₂…V_b)*(K₁K₂…K_c)*(A₁A₂…A_d) (1)

in S300, the graded i-track cache threshold Y_iJudging that the number of the cells cached in the i-way of the grading is smaller than the caching threshold Y of the i-way of the grading for the system_iAnd no gear P is in the detection position_iThe method comprises the following steps that (1) battery cell feeding is carried out, a system issues a deficient gear feeding instruction to an upper blanking position i as a process starting point, the deficient gear battery cell feeding is realized through the feeding and blanking position i, the system is transferred to a battery cell detection station to complete a detection process, and finally the system is transferred to a stepping i track to be cached as a process end point, wherein the time for completing the process is T(s); each string of cores in a module uses P_iNumber of gear positions M_Pi(ii) a The number M of each series of electric cores in one module; production line efficiency E (time required to process each cell; only/s);

Y_i＝T/(M*E/M_Pi)*1.5 (2)

in general, in the embodiment of the invention, the battery cell loading passes through the detection station, the qualified battery cell is detected, the battery cell gear is determined, if the battery cell belongs to the battery cell of the group matching gear, and the number of the battery cells cached in the i-channel grading way is less than the threshold value Y_iThe battery cell is transferred to a stepping i-channel cache by a transfer trolley; if the battery cell does not belong to the group matching gear, the battery cell with the redundant gear is taken off by the quick off-line + NG channel to the upper blanking position i; detecting unqualified cells, and realizing NG cell blanking from a conveying trolley to an NG blanking position through a coil inserting and NG fast channel; the empty conveying trolley waits for feeding from the upper material level through the empty trolley return passage. According to the group rule, the electric core that grades i says transports to the position of joining in marriage in proper order through the conveying trolley according to the rule of joining in marriage, accomplishes and joins in marriage the group, snatchs the electric core by piling up the robot and rolls off the production line, and empty conveying trolley waits the material loading through empty car return channel to the material loading level. When the system detects that the graded i-track cache battery cell is smaller than the threshold value Y_iAnd no gear P is in the detection position_iThe electric core supplied materials, the system suggestion goes up unloading i position and realizes not enough gear electricity core material loading, detects through feed supplement fast channel to detecting the station by the conveying dolly, detects qualified fortune to stepping i way buffer memory, waits for the group of joining in marriage.

On the other hand, the invention also discloses a battery cell grading and grouping system based on the ACOPOStrak flexible transportation system, which comprises the following units:

the feeding unit is used for grabbing the mixed battery cell onto a conveying trolley of the ACOPOStrak through a feeding robot;

cell detection and gear division unit for cell incoming material detection, NG offline and gear P_iDividing;

a cell flow direction judgment unit for judging whether the cell is a gear P required by the group matching_iBattery cell and gear P_iJudging the flow direction of the battery cell according to the cache number;

the insufficient gear battery cell feeding unit is used for feeding the insufficient gear battery cells;

and the gear electric core matching unit is used for sequentially transferring the electric core in the gear i channel to the matching position through the conveying trolley according to the matching rule, completing matching and grabbing the electric core for inserting the wire by the stacking robot.

The battery cell grading and grouping system based on the acopstrak flexible transportation system comprises hardware and software, wherein the hardware is a battery cell grading and grouping device based on the acopstrak flexible transportation system, and a related control part is embedded in a control algorithm.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

The present application is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the application. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

The above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (7)

1. A battery core grading and grouping method based on an ACOPOStrak flexible transportation system is based on the ACOPOStrak flexible transportation system and is characterized in that:

the ACOPOStrak flexible transportation system is set into a battery cell grading and grouping device which comprises a battery cell loading position, a detection position, each gear grading channel, an off-line + NG quick channel, a grouping position, an empty vehicle return channel, each gear loading and unloading position, a material supplementing quick channel, an NG blanking channel and a conveying trolley;

the method comprises the following steps:

s100, grabbing the mixed-gear battery cell to a conveying trolley of an ACOPOStrak through a feeding robot;

s200, detecting battery cell incoming materials, inserting line in NG and shifting P_iDividing;

s300, according to whether the gear P is required by matching_iBattery cell and gear P_iJudging the flow direction of the battery cell according to the cache number;

s400, feeding the battery cell with insufficient gears;

s500, the battery cells in the i-channel are sequentially transferred to a matching position through a conveying trolley according to matching rules, matching is completed, and the battery cells are grabbed by a stacking robot to be offline.

2. The ACOPOStrak flexible transportation system-based battery cell grading grouping method according to claim 1, wherein: s200 carries out battery cell incoming material detection, NG rolls off production line and gear P_iDividing;

the method specifically comprises the following steps:

the conveying trolley carrying the battery cell is transferred to a detection position, two code scanning devices are installed at the detection position, a two-dimensional code on a battery cell top cover and a two-dimensional code on the conveying trolley are respectively read, the battery cell with the qualified code reading is automatically bound with the conveying trolley carrying the battery cell by a system, the capacity C, the voltage V, K value and other parameters of the battery cell are called according to the read two-dimensional code on the battery cell top cover, the conveying trolley reading the battery cell two-dimensional code with abnormity is marked as an NG battery cell, and the battery cell is transferred to an NG blanking position through a quick channel by the conveying trolley to realize the off-line;

based on the battery cell capacity C, the voltage V, K value and other parameters, the gear P of the battery cell is determined according to the threshold ranges of the different gear capacity C, the voltage V, K value and other parameters_i。

3. The ACOPOStrak flexible transportation system-based battery cell grading grouping method according to claim 1, wherein: s300, according to whether the gear P is required by matching_iBattery cell and gear P_iJudging the flow direction of the battery cell according to the cache number; the method specifically comprises the following steps:

judging whether the gear to which the battery cell belongs is the gear required by matching the group, and judging the gear P if the gear to which the battery cell belongs is the gear required by matching the group_iWhether the number of the cached battery cells on the grading i channel is smaller than a channel i cache threshold Y or not_iIf the value is less than the cache threshold Y of the i-way of the stepping_iThe battery cell is transferred to a stepping i-channel cache through a transfer trolley; if the value is larger than the stepping i-track cache threshold value Y_iThe battery cell is a redundant gear battery cell, and the battery cell is fed to the upper part through the quick channel by an i-position to realize the offline of the redundant gear battery cell through the conveying trolley; if the battery cell does not belong to the gear required by matching, the battery cell is an unnecessary gear battery cell, and the battery cell passes through the quick channel through the conveying trolley to discharge to the upper part and the lower part of the battery cell in an i-position real stateAnd (5) discharging the redundant gear battery cell.

4. The ACOPOStrak flexible transportation system-based battery cell grading grouping method according to claim 1, wherein: s400, feeding the battery cell with insufficient gears;

the method comprises the following steps: judging the number of the cells cached in the i-track stepping mode, and if the number of the cells cached in the i-track stepping mode is smaller than a caching threshold Y of the i-track stepping mode_iAnd no gear P is in the detection position_iBattery core supplied material, then gear P_iThe battery cell is a battery cell with insufficient gears, and the battery cell with insufficient gears is loaded and unloaded in an i-position mode; the battery cell with insufficient gears is conveyed to a detection position through a conveying trolley after being on-line, two code scanning devices are installed at the detection position, two-dimensional codes on a top cover of the battery cell and two-dimensional codes on the conveying trolley are respectively read, the battery cell with qualified code reading is automatically bound with the conveying trolley carrying the battery cell by a system, and the battery cell is conveyed to a stepping i-lane cache by the conveying trolley; the conveying trolley for reading the two-dimensional code of the battery cell is marked as the NG battery cell, and the battery cell is conveyed to the NG discharging position through the quick channel through the conveying trolley to realize the NG battery cell offline.

5. The ACOPOStrak flexible transportation system-based battery cell grading grouping method according to claim 2, characterized in that: in S200, the threshold ranges of the different gear capacities C, the voltage V, K values, and other parameters are determined according to the battery cell performance factor capacity class C₁C₂…C_aVoltage class V₁V₂…V_bAnd K value grade K₁K₂…K_cAnd other influencing factors A₁A₂…A_dDividing threshold ranges of all influence factors of different gears, and determining the number n of the gears divided by the battery cell;

n＝(C₁C₂…C_a)*(V₁V₂…V_b)*(K₁K₂…K_c)*(A₁A₂…A_d) (1)。

6. the ACOPOStrak-based flexible transportation system cell grading grouping of claim 3The method is characterized in that: step i cache threshold Y in S300_iJudging that the number of the cells cached in the i-way of the grading is smaller than the caching threshold Y of the i-way of the grading for the system_iAnd no gear P is in the detection position_iThe method comprises the following steps that (1) battery cell feeding is carried out, a system issues a deficient gear feeding instruction to an upper blanking position i as a process starting point, the deficient gear battery cell feeding is realized through the feeding and blanking position i, the system is transferred to a battery cell detection station to complete a detection process, and finally the system is transferred to a stepping i track to be cached as a process end point, wherein the time for completing the process is T(s); each string of cores in a module uses P_iNumber of gear positions M_Pi(ii) a The number M of each series of electric cores in one module; the production line efficiency E is the time required for processing each cell; only/s;

Y_i＝T/(M*E/M_Pi)*1.5 (2)。

7. the utility model provides a battery core stepping system of joining in marriage based on flexible transport system of ACOPOStrak which characterized in that: the method comprises the following units:

the feeding unit is used for grabbing the mixed battery cell onto a conveying trolley of the ACOPOStrak through a feeding robot;

cell detection and gear division unit for cell incoming material detection, NG offline and gear P_iDividing;

a cell flow direction judgment unit for judging whether the cell is a gear P required by the group matching_iBattery cell and gear P_iJudging the flow direction of the battery cell according to the cache number;

the insufficient gear battery cell feeding unit is used for feeding the insufficient gear battery cells;

and the gear electric core matching unit is used for sequentially transferring the electric core in the gear i channel to the matching position through the conveying trolley according to the matching rule, completing matching and grabbing the electric core for inserting the wire by the stacking robot.

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